Hierarchy of management that covers different levels of management
CURRENT STATUS AND POTENTIAL OF BIOLOGICAL CONTROL OF COTTON INSECT AND DISEASE PESTS
1.
2. Presenter
Hem Raj Pant
frenndlyhem01234@gmail.com
Msc. Ag
Department of Plant pathology
AFU- Agriculture and Forestry University
Rampur, chitwan
www.afu.edu.np
A Presentation on
CURRENT STATUS AND POTENTIAL OF BIOLOGICAL
CONTROL OF COTTON INSECT AND DISEASE PESTS
3. What isbiologicalcontrol
Biological control is "the action of
parasites, predators, or pathogens in
maintaining another organism's population
density at a lower average than would
occur in their absence".
This management technology has
received much attention in recent times.
4. Why biologicalcontrol
Highly economical in a long run
Selective with no side effects
Self propagating and self-perpetuating
Pest resistance to BCAs is virtually unknown
No harmful effects on humans, livestock's and
other organisms
Efficiency, greater ability to search their prey
Improved quality of produce
Compatible with most of the IPM components
5. WHY not common in use in Nepal
Very few researches have been conducted in this field in our
country
Expensive at startup
Insufficient technical Manpower knowledge
Doesn't completely destroy a pest
Does not have a broad-spectrum as insecticides & fungicides
7. Parasitoid
Each parasitoids requires only one host, which it kills for its
development into a free living adult.
Parasitoids are of the same size as the hosts , or sometimes even
smaller.
Mechanism
Examples
Trichogramma chilonis effective against
Pink bollworm of Cotton
Eggs of female Trichogramma chilonis
The Female parasitoid lays eggs inside or on an
insect host. Legless larva on hatching feed on the hosts
internally or externally.
8. Pathogen
Pathogens are disease causing organisms e.g. Bacteria, Fungi, Viruses,
Protozoa and Nematodes in insect and disease pests which kill their
host or debilitate the future generation.
Mechanism
Examples
Seed treatment with Trichoderma viride
prevents cotton against Cotton seedling disease,
Sclerotium rolfsii
The infected insects are unable to feed properly ,remain
stunted, lose their body colour and get paralysed. Dead insects
are often found hanging on the plants, or a fungal growth on
the body of dried insect could be easily located in the field
9. Predator
These are free living and larger in size than their prey, requiring several
preys to complete their life cycle. Some smaller predators release a
powerful poison, use a trap or hunt in groups to be more effective.
Mechanism
Green lacewings (very common and important
predator of cotton pests).
The female lays small pale green, oval shaped eggs
at the end of long silken stalks, which ultimately
turns grey. The larva have well developed legs and
pincer like jaws with which they suck the body
fluids from the prey
10. TYPES OF BIOLOGICAL PEST CONTROL
1. Importation or classical biological control: The control of a pest species by
introduced natural enemies
2. Augmentation: Propagation (mass culturing) and release of NE to increase its
population. Two types,
(i) Inoculative release: Control expected from the progeny and subsequent
generations only.
(ii) Inundative release: NE mass cultured and released to suppress pest
directly e.g. Trichogramma spp. (egg parasitoid), Chrysoperla carnia
(Predator)
3. Conservation: Actions that preserve and increase NE by environmental
manipulation e.g. Use of selective insecticides, Provide alternate host for NE.
11. (Gossypium hirsutum)
INTRODUCTION
Cotton is referred to as “King of Fibres” and also known as “White
Gold”.
It is also backbone of textile industry.
China is the world’s largest producer of cotton
45% world’s fiber need is met from cotton.
10% of world’s edible oil is met from cotton.
Cotton in Nepal
143 ha and total production of 127 Mt with productivity of 0.89
ton/ha (MoAD, 2016/17)
12. IMPORTANCE OFCOTTON
It is cultivated primarily for lint.
Raw cotton is also used for medical and surgical purpose.
Linters are used cushions, pillows etc.
Linters Also used for high grade paper, rayon, films,
explosives.
Seed crushed for edible oil.
Cakes and meals are excellent cattle feed.
13. POTENTIAL BIOLOGICAL CONTROL OF MAJOR INSECT PEST OF COTTON
1. American bollworm/Fruit borer:
Helicoverpa armigera Family: Noctuidae
Order: Lepidoptera
Biological control
Inundative release of egg parasitoid,
Trichogramma spp., or Scambus lineipes at
15 days interval 3 times from 45 DAS
Releasing predator Chrysoperla carnea @
1, 00, 000/ha at 6th, 13th and 14th week
after sowing.
Fig.Feeding injury Fig.Circular bore hole
Fig. Larva andAdult
14. 2. Pink bollworm:
Pectinophora gossypiella
Family: Gelechiidae Order:
Lepidoptera
Biological control
Release of egg parasitoids
Trichogramma chilonis, Elasmus
johnstoni and Goniozus spp
Timely spraying with formulations
of Bacillus thuringiensis can also
be effective
15. 3. Spotted bollworm:
Earias vittella
Family: Noctuidae Order: Lepidoptera
Biological control
Release egg parasitoid Trichogramma
chilonis, T. brasiliensis, and larval
parasitoids Chelonus blackburni or Bracon
brevicornis or Apanteles sp. at 35 to 70
days.
Conserve and encourage the activity of the
spiders Thomisus sp. and Neosiana sp. Fig. Larva Fig. bore hole and rotting
Fig. Adult
16. 4. Armyworm /Tobacco cutworm:
Spodoptera litura
Family: Noctuidae Order: Lepidoptera
Biological control
Wasp parasitoids include Cotesia
marginniventris, Chelonus texanus and C.
remus.
Predators include ground beetles, flower
bugs.
Bioinsecticides containing Bacillus
thuringiensis can be sprayed.
Fig. Larva
Fig. Adult
17. 5. Cotton aphid
Aphis gossypii
Family: Aphididae Order: Homoptera
Biological control
The parasitic wasp Lysiphlebus testaceipes
and a group of aphid predators (including
the lady beetles Hippodamia convergens
and Coccinella septempunctata and the
predatory larvae of syrphid flies) are
important natural enemies (Goven, 2003)
Fig. Affected leaf
Fig. Aphid
18. 6. Whitefly
Bemisia tabaci
Family: Aleyrodidae Order: Hemiptera
Biological control
Several wasps, including species in the
genera Encarsia and Eretmocerus,
parasitize whiteflies. Whitefly nymphs are
also preyed upon by bigeyed bugs,
lacewing larvae, and lady beetles (Mart,
2004).
Fig. Affected leaf
Fig. Whitefly
19. 7. Leafhopper
Amrasca bigutella biguttula
Family: Cicadellidae Order: Hemiptera
Biological control
Release predators viz., Chrysopa
carnea.
Jassids are parasitized by parasitoid
wasps like Anagrus flaveolus and
Stethynium tridavatum
Fig. Affected leaf
Fig. Leafhopper
22. 1. Angular leaf spot of Cotton
Causal organism: Xanthomonas malvacearum
Biological control:
Application of talc-based powder
formulations containing the bacteria
Pseudomonas fluorescens and Bacillus
subtilis are efficient against X.
malvacearum.
POTENTIAL BIOLOGICAL CONTROL OF MAJOR DISEASES OF COTTON
24. 3. Alternaria leaf spot of cotton
Causal organism: Alternaria termis,
A.macrospora
Biological control:
Seed treatment with Pseudomonas
fluorescens (10g/kg seeds) and
spraying of 0.2% every 10 days
reduce the infection significantly.
25. 4. Fusarium wilt of cotton
Causal organism: Fusarium moniliform,
Fusarium vasifectum
Biological control:
Several biological control agents,
including bacteria and nonpathogenic
stains of F.oxysporum that compete
with the pathogens have been used to
control fusarium wilt.
T. viride can also be used to treat the
seeds (10 gm/kg seed).
26. 5. Root rot of cotton
Causal organism: Macrophomina
phaseolina
Biological control:
Some species of fungus Trichoderma
showed promising results in that
they significantly increased survival
of treated seedlings and are being
considered for commercialization
27. 6. Grey mildew of cotton
Causal organism: Mycosphaerella
areola
Biological control:
Seed treatment with products
containing Pseudomonas fluorescens
(10g/kg seeds) can be done.
Other bacteria (Bacillus circulans
and Serratia marcescens) have been
used to control.
28. 7. Root knot nematode of cotton
Causal organism: Meloidogyne incognita,
M. arenaria
Biological control:
Bacterial treatments of Soils and seeds
with biopesticides containing
Pseudomonas Fluorescens, Pasteuria
penetrans or Bacillus thuringiensis also
work.
Nematode feeding fungi (Arthrobotrys
spp. and Monacrosporium spp.) or fungi
parasitizing on eggs and females
(Pochoina chlamydosporia and
Paecilomyces lilacinus) are another
solution.